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13.3 Arc Length and Curvature

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Length of a Curve

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Length and Curve

We have defined the length of a plane curve with

parametric equations x = f(t), y = g(t), a ≤ t ≤ b, as the limit of lengths of inscribed polygons and, for the case where f' and g' are continuous, we arrived at the formula

The length of a space curve is defined in

exactly the same way (see Figure 1).

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Length and Curve

Suppose that the curve has the vector equation, r(t) =

f(t), g(t), h(t)

, a ≤ t ≤ b, or, equivalently, the

parametric equations x = f(t), y = g(t), z = h(t), where f', g', and h' are continuous.

If the curve is traversed exactly once as t increases from a to b, then it can be shown that its length is

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Length and Curve

Notice that both of the arc length formulas (1) and (2) can be put into the more compact form

because, for plane curves r(t) = f(t)i + g(t)j,

and for space curves r(t) = f(t)i + g(t)j + h(t)k,

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Example 1

Find the length of the arc of the circular helix with vector

equation r(t) = cos t i + sin t j + t k from the point (1, 0, 0) to the point (1, 0, 2π).

Solution:

Since r'(t) = –sin t i + cos t j + k, we have

The arc from (1, 0, 0) to (1, 0, 2π) is described by the

parameter interval 0 ≤ t ≤ 2π and so, from Formula 3, we have

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Length and Curve

A single curve C can be represented by more than one vector function. For instance, the twisted cubic

r1(t) =

t, t2, t3

1 ≤ t ≤ 2 could also be represented by the function

r2(u) =

eu, e2u, e3u

0 ≤ u ≤ ln 2 where the connection between the parameters t and u is given by t = eu.

We say that Equations 4 and 5 are parametrizations of

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Length and Curve

If we were to use Equation 3 to compute the length of C using Equations 4 and 5, we would get the same answer.

In general, it can be shown that when Equation 3 is used to compute arc length, the answer is independent of the

parametrization that is used.

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The Arc Length Function

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The Arc Length Function

Now we suppose that C is a curve given by a vector function

r(t) = f(t) i + g(t) j + h(t) k a ≤ t ≤ b

where r' is continuous and C is traversed exactly once as t increases from a to b.

We define its arc length function s by

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The Arc Length Function

Thus s(t) is the length of the part of C between r(a) and r(t). (See Figure 3.)

Figure 3

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The Arc Length Function

If we differentiate both sides of Equation 6 using Part 1 of the Fundamental Theorem of Calculus, we obtain

It is often useful to parametrize a curve with respect to arc length because arc length arises naturally from the shape of the curve and does not depend on a particular coordinate system.

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The Arc Length Function

If a curve r(t) is already given in terms of a parameter t and s(t) is the arc length function given by Equation 6, then we may be able to solve for t as a function of

s: t = t(s).

Then the curve can be reparametrized in terms of s by substituting for t: r = r(t(s)).

Thus, if s = 3 for instance, r(t(3)) is the position vector of the point 3 units of length along the curve from its starting point.

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Example 2

Reparametrize the helix r(t) = cos t i + sin t j + t k with respect to arc length measured from (1, 0, 0) in the direction of increasing t.

Solution:

The initial point (1, 0, 0) corresponds to the parameter value t = 0. From Example 1 we have

and also

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Example 2 – Solution

Therefore and the required reparametrization is obtained by substituting for t:

cont’d

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Curvature

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Curvatures

A parametrization r(t) is called smooth on an interval I if r' is continuous and r'(t) ≠ 0 on I.

A curve is called smooth if it has a smooth parametrization.

A smooth curve has no sharp corners or cusps; when the tangent vector turns, it does so continuously.

If C is a smooth curve defined by the vector function r, recall that the unit tangent vector T(t) is given by

and indicates the direction of the curve.

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Curvatures

From Figure 4 you can see that T(t) changes direction very slowly when C is fairly straight, but it changes direction

more quickly when C bends or twists more sharply.

Figure 4

Unit tangent vectors at equally spaced points on C

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Curvatures

The curvature of C at a given point is a measure of how quickly the curve changes direction at that point.

Specifically, we define it to be the magnitude of the rate of change of the unit tangent vector with respect to arc length.

(We use arc length so that the curvature will be

independent of the parametrization.) Because the unit tangent vector has constant length, only changes in direction contribute to the rate of change of T.

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Curvatures

The curvature is easier to compute if it is expressed in

terms of the parameter t instead of s, so we use the Chain Rule to write

But ds/dt = |r'(t)| from Equation 7, so

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Example 3

Show that the curvature of a circle of radius a is 1/a.

Solution:

We can take the circle to have center the origin, and then a parametrization is

r(t) = a cos t i + a sin t j

Therefore r'(t) = –a sin t i + a cos t j and | r'(t)| = a so

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Example 3 – Solution

This gives | T'(t)| = 1, so using Equation 9, we have

cont’d

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Curvature

The result of Example 3 shows that small circles have large curvature and large circles have small curvature, in

accordance with our intuition.

We can see directly from the definition of curvature that the curvature of a straight line is always 0 because the tangent vector is constant.

Although Formula 9 can be used in all cases to compute the curvature, the formula given by the following theorem is often more convenient to apply.

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Curvature

For the special case of a plane curve with equation y = f(x), we choose x as the parameter and write r(x) = x i + f(x) j.

Then r'(x) = i + f'(x) j and r''(x) = f''(x) j.

Since i × j = k and j × j = 0, it follows that r'(x) × r''(x) = f''(x) k.

We also have and so, by Theorem 10,

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The Normal and Binormal Vectors

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The Normal and Binormal Vectors

At a given point on a smooth space curve r(t), there are many vectors that are orthogonal to the unit tangent vector T(t).

We single out one by observing that, because | T(t)| = 1 for all t, we have T(t) T'(t) = 0, so T'(t) is orthogonal to T(t).

Note that T'(t) is itself not a unit vector.

But at any point where ≠ 0 we can define the principal unit normal vector N(t) (or simply unit normal) as

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The Normal and Binormal Vectors

The vector B(t) = T(t) × N(t) is called the binormal vector.

It is perpendicular to both T and N and is also a unit vector.

(See Figure 6.)

Figure 6

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Example 6

Find the unit normal and binormal vectors for the circular helix

r(t) = cos t i + sin t j + t k

Solution:

We first compute the ingredients needed for the unit normal vector:

r'(t) = –sin t i + cos t j + k

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Example 6 – Solution

This shows that the normal vector at any point on the helix is horizontal and points toward the z-axis.

The binormal vector is

B(t) = T(t) × N(t)

cont’d

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The Normal and Binormal Vectors

The plane determined by the normal and binormal vectors N and B at a point P on a curve C is called the normal

plane of C at P.

It consists of all lines that are orthogonal to the tangent vector T.

The plane determined by the vectors T and N is called the osculating plane of C at P.

The name comes from the Latin osculum, meaning “kiss.” It is the plane that comes closest to containing the part of the curve near P. (For a plane curve, the osculating plane is simply the plane that contains the curve.)

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The Normal and Binormal Vectors

The circle that lies in the osculating plane of C at P, has the same tangent as C at P, lies on the concave side of C

(toward which N points), and has radius ρ = 1/ (the

reciprocal of the curvature) is called the osculating circle (or the circle of curvature) of C at P.

It is the circle that best describes how C behaves near P; it shares the same tangent, normal, and curvature at P.

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The Normal and Binormal Vectors

We summarize here the formulas for unit tangent, unit normal and binormal vectors, and curvature.

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